KR20190111690A - DC-DC Converter Control Method for Photovoltaic System in Stand-alone Power Generation System - Google Patents

Abstract

The present invention relates to a photovoltaic DC-DC converter control method in a stand-alone system. To minimize element damage and power outages due to a battery failure, battery voltage is checked in real time to control a DC-DC converter for photovoltaic power adjustment to output constant voltage when detecting an emergency situation so as to prevent a sharp increase of the voltage due to voltage stabilization of a DC-Link terminal in case of the battery failure, thereby increasing system stability and reliability.

Description

DC-DC Converter Control Method for Photovoltaic System in Stand-alone Power Generation System}

The present invention relates to a method for controlling a solar DC-DC converter under a stand-alone system, and more specifically, for minimizing device burnout and power failure due to a battery failure, by checking a battery voltage in real time to detect solar power in an emergency situation. By controlling the DC-DC converter to output a constant voltage, it is possible to control the DC-DC converter for solar power under the stand-alone system that can prevent the sudden rise of the voltage due to the voltage stabilization of the DC-Link stage in case of battery failure. It is about.

As is well known, there is a continuing investment and interest in the development of renewable energy that can replace existing fossil energy today.

Renewable energy sources, including wind, fuel cells and solar, are increasingly moving towards the use of sustainable, environmentally friendly materials, and will become an indispensable, rather than selective use in the future.

The advantages of solar power are widely known to be universal facts by various media and materials. However, it is also true that photovoltaic power generation is not a large part of the overall power system compared to existing energy sources such as oil, coal, gas and nuclear power.

However, if economic factors are complemented in the light of the current trend, the utility of photovoltaic power generation is expected to increase dramatically.

Due to the nature of power generation, efficiency is at the heart of system design. The same characteristics also apply to a photovoltaic power generation system. Therefore, various techniques are discussed to achieve higher efficiency.

In addition, solar power generation must perform a maximum power point tracking (MPPT) algorithm to improve power generation efficiency.

These solar power generation is rainy or cloudy day is low because the amount of solar radiation can not produce the amount of power that satisfies the load is not constituted alone, it is to charge the battery using a separate diesel generator.

1 is a typical stand-alone solar power system as an example of a solar array (2), DC-DC converter (4), three-phase inverter 10, battery charger 14, battery (8), fuel such as a diesel generator The generator 12 is comprised.

The DC-DC converter 4 is a buck converter type that acts to step down the voltage, performs a MPPT function that tracks the maximum point of power generated in the solar array 2, and the three-phase inverter 10 The constant voltage / constant frequency control of the power thus produced serves to supply power to the system stably.

On the other hand, by connecting the battery (8) to the DC-Link unit (6) when the energy produced from sunlight is left to charge or discharge at night to supply power to the load. If the rain lasts for a long time or the day when the solar radiation is low for a long time, it is difficult to supply power to the load due to the lack of solar power, and the power generated by starting the diesel generator is used to charge the battery using the battery charger.

In such a system, the battery plays a very important role in maintaining a stable DC-Link voltage and at the same time providing a stable power supply to the load.

However, if the battery fails at this time, the battery side contactor is opened and the DC-Link terminal voltage becomes unstable. In some cases, when the load is very small compared to the amount of power generated, in case of battery failure, the DC-Link terminal voltage may momentarily increase to near the open voltage of the photovoltaic array, resulting in a device burnout in the DC-DC converter and three-phase inverter. May adversely affect

Therefore, due to the DC-Link stage voltage that becomes unstable during battery failure, the three-phase inverter performs protection operations such as DC stage undervoltage, overvoltage, and AC stage undervoltage, and eventually stops, causing a power failure.

Prior Art Documents: 'Research of Independent Solar Power Converter', Journal of the Korean Solar Energy Society, Vol. 31, No. 2, 2011.

The present invention has been made in view of the above-described prior art, and in order to minimize device burnout and power failure due to a battery failure, the battery voltage is checked in real time and a constant voltage is applied to the solar power control DC-DC converter when an emergency is detected. Its purpose is to provide a solar DC-DC converter control method under a standalone system that can prevent the sudden rise in voltage due to the voltage stabilization of the DC-Link stage in case of battery failure. .

In order to achieve the above object, according to a preferred embodiment of the present invention, a DC / DC converter control method for voltage control of the DC link unit, comprising: a) detecting a battery voltage; b) determining whether the detected voltage of the battery is outside the set voltage range; c) if the detected voltage of the battery is within the set voltage range, the converter control unit maintaining an MPPT (maximum power point tracking) control mode; d) If the detected voltage of the battery is out of the set voltage range, the converter control unit switches to the emergency operation mode and controls to output a constant voltage to the DC link unit, characterized in that the DC-DC converter for solar power under the standalone system A control method is provided.

Preferably, the step b) is a step of detecting whether the battery voltage is "0" is provided a solar DC-DC converter control method under a standalone system.

Preferably, the step b) is linked to the smart grid is a step of determining whether the battery voltage considering the total load is out of the set range is provided a solar DC-DC converter control method under a standalone system.

Preferably, the step d) is provided with a control method of the DC-DC converter for solar power under the stand-alone system, characterized in that it comprises the step of controlling the converter to turn off the switch (S1) on the MPPT operation path.

Preferably, in the step d), at the time of mode switching, a control including an operation of temporarily switching the switch S2 for initializing the integrator value and multiplying the integrator output by a predetermined gain is performed to increase the response speed when the mode is changed. Provided is a method for controlling a DC-DC converter for solar power under a standalone system.

Preferably, the step d) is a process for controlling to compensate for the error between the battery voltage set voltage and the output voltage of the DC link unit is provided a solar DC-DC converter control method under a stand-alone system.

The DC-DC converter control method for solar power under the standalone system according to the present invention compares a predetermined voltage with a battery voltage to determine whether or not a battery is broken, and provides fast constant voltage in case of battery failure. It has the advantage of preventing system damage and increasing system reliability by providing uninterrupted service to consumers.

1 is a block diagram showing the configuration of a typical standalone solar power system,
FIG. 2 is a block diagram showing the configuration of a photovoltaic power generation system under a standalone system to which a solar DC-DC converter control apparatus is added according to an embodiment of the present invention; FIG.
3 is a configuration diagram showing the configuration of the solar DC-DC converter control unit included in FIG.
4 is a flow chart showing a control flow of the solar DC-DC converter under the stand-alone system according to an embodiment of the present invention,
5 is a simulation waveform diagram of a conventional system;
Figure 6 is an output waveform due to the DC-DC converter control device for solar according to an embodiment of the present invention,
FIG. 7 is a waveform diagram illustrating an output waveform in which a DC-DC converter is controlled and stabilized in a transient state due to the enlarged waveform of FIG. 6.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

FIG. 2 is a block diagram showing the configuration of a photovoltaic power generation system under a stand-alone system to which a solar DC-DC converter control apparatus is added according to an embodiment of the present invention. FIG. 3 is a solar DC- diagram included in FIG. 2. It is a block diagram which shows the structure of a DC converter control part.

Referring to this, the solar power generation system under the stand-alone system to which the solar DC-DC converter control apparatus is added according to an embodiment of the present invention, in order to minimize the device burnout and power failure due to the battery failure, the battery voltage in real time Independent system that checks and regulates solar power control DC-DC converter to output constant voltage in case of emergency and prevents sudden rise of voltage due to voltage stabilization of DC-Link stage in case of battery failure. It is a system that can control the solar DC-DC converter.

More specifically, the photovoltaic power generation system under the stand-alone system to which the solar DC-DC converter control apparatus is added according to an embodiment of the present invention is basically a photovoltaic array (2), a DC-DC converter (4), 3 Phase inverter 10, battery charging section 14, the battery 8, and a fuel generator 12 such as a diesel generator is configured.

At this time, the DC-DC converter 4 is a buck converter type that acts to step down the voltage and performs an MPPT function that follows the maximum point of the power generated in the solar array 2. That is, the DC / DC converter 4 converts the output voltage V _PV of the solar array 2 obtained by converting solar energy into electrical energy to a predetermined voltage.

In addition, the photovoltaic power generation system 100 of the present invention includes an output terminal of the DC / DC converter 4 connected to the solar array 2 for converting sunlight into electrical energy, and an output voltage from the battery 8. A three-phase DC / AC inverter for converting the DC link unit 6 to generate a DC voltage VDC and converting the DC voltage VDC from the DC link unit 6 into a predetermined AC voltage Vac. (10).

The photovoltaic array 2 is divided into a time when there is sunlight, such as daytime, and a time when there is no sunlight, such as night time, and when there is sunlight, solar power generation is performed to generate effective PV power by solar power generation. In the case where solar power generation is not performed, it is impossible to generate valid PV power. As described above, since the solar power generation is not performed in a constant manner depending on the presence or absence of solar light, the maximum power point tracking that tracks the maximum power point among the power generated by the solar array 2 is performed. It should be controlled to generate maximum power through MPPT: Maximum Power Point Tracking.

The fuel generator 12 is a device for generating power through a fuel, such as a diesel generator, having a battery charging unit 14 at an output end thereof, and an output terminal of the battery charging unit 14 connected to the battery 8. When the voltage of the battery 8 drops below a predetermined value, the fuel generator 12 is operated to generate power to achieve an uninterruptible system.

On the other hand, the photovoltaic power generation system 100 of the present invention is a voltage sensing unit 20 for detecting the voltage of the battery 8 and, in particular, when the detected voltage of the battery is outside the set voltage range, the detected battery voltage is A converter that controls the DC-DC converter 4 so that a constant voltage is input to the DC link unit 6 by switching to the emergency mode and turning off the MPPT mode when it is determined to be “0” or close to “0”. The control unit 22 is further included.

In this case, the converter controller 22 may be preferably linked with the smart grid to determine whether the battery voltage considering the total load is out of the set range, thereby enabling stabilization of the system in a wider range.

The control flow of the solar DC-DC converter under the stand-alone system according to the embodiment of the present invention having the above-described configuration will be described with reference to the drawings.

4 is a flowchart illustrating a control flow of a solar DC-DC converter under a standalone system according to an embodiment of the present invention, and FIG. 6 is a flowchart of a DC-DC converter control device for solar cells according to an embodiment of the present invention. Output waveform, FIG. 7 is a waveform diagram illustrating an output waveform in which a DC-DC converter is controlled and stabilized in a transient state due to the enlarged waveform of FIG. 6.

First, the battery 8 is charged by the operation of the solar array 2 and the fuel generator 12, and stably loads through the DC-DC converter 4 and the three-phase DC-AC inverter 10. In the system for supplying power to (16), for the voltage control of the DC link unit to prevent the breakdown voltage generated suddenly in a specific emergency situation, preferably in the failure state of the battery 8, affecting the component or the interlocking device. The DC / DC converter control flow is operated through the converter controller 22.

As described above, the standalone system according to an embodiment of the present invention is controlled to generate maximum power through Maximum Power Point Tracking (MPPT), wherein the voltage sensing unit 20 is Always detect battery voltage.

That is, it is determined whether the detected voltage of the battery is out of the set voltage range.

At this time, if the detected voltage of the battery is within the set voltage range, the converter controller maintains the MPPT (maximum power point following) control mode, and if the detected voltage of the battery is out of the set voltage range, it is regarded as a failure of the battery 8. Upon determining, the converter controller 22 switches to the emergency operation mode and controls the constant voltage to be output to the DC link unit.

Preferably, the determining whether the battery 8 is a failure is a case of detecting whether the battery voltage is “0” or more preferably, the battery voltage in consideration of the total load in connection with the smart grid is set within the set range. This is the case when judging whether the deviation.

If the conventional system is applied when the battery 8 fails, as shown in Fig. 5, a simulation waveform is generated.

That is, the first waveform is the battery fault signal, the second waveform is the DC-Link voltage, and the third waveform is the three-phase inverter output voltage waveform. As shown in the figure, when the battery breaks down, the DC-Link part voltage is momentarily increased, and the inverter 10 detects an overvoltage of the DC-Link part 6 and stops it. Thus, as shown in the figure, a power failure occurs in the customer who is the load.

Therefore, in the system of the present invention, when a failure signal of the battery 8 is applied, the converter controller 22 controls to turn off the switch S1 on the MPPT operation path, and at the time of mode switching to the emergency mode, The switch S2, which initializes the integrator value, is temporarily switched and at the same time, the control including the operation of multiplying the integrator output value by a certain gain is performed to increase the response speed when the mode is changed.

In addition, as illustrated in FIG. 3, the converter controller 22 controls to compensate for an error between the battery set voltage and the output voltage of the DC link unit.

More specifically, the input voltage command value for MPPT is generated by sensing the voltage and current of the PV side, and the input terminal voltage control is performed by using the PI controller to follow this command value. If the battery is notified, the MPPT control stops and changes to the output voltage control.

Here, S1 switch is open in MPPT control and closed in output voltage control. S2 switch is open during MPPT control, but is closed once and then open immediately when it is changed to output voltage control.

The reason is that by initializing the remaining integrator value and multiplying the integrator output value by a certain gain, the response speed can be increased quickly and the overshoot can be reduced at the transition point where the control is changed.

6 shows an output waveform when the controller shown in FIG. 3 is used.

When the battery failure occurs, the output voltage control mode is changed to maintain the voltage of the DC-Link unit 6 can be stably supplied power without a power failure at the customer. Vdc_ref is a DC terminal voltage command value and makes a command value with the voltage of the final DC_Link part 6 at the time of battery failure.

 7 shows that the DC-Link part 6 voltage is stably maintained in the transient state in which the controller changes to the magnified waveform of FIG. 6, and the output voltage of the inverter 10 is also maintained at 240 V and 50 Hz. It is shown.

On the other hand, the DC-DC converter control method for solar power under the stand-alone system according to an embodiment of the present invention is not limited to the above-described embodiment, various modifications are possible without departing from the technical gist of the invention.

2: solar array, 4: DC-DC converter,
6: DC link, 8: battery,
10: three-phase DC-AC converter, 12: fuel generator,
14: battery charging unit, 16: load,
20: voltage detection unit, 22: converter control unit.

Claims (6)

In the DC / DC converter control method for voltage control of the DC link unit,
a) detecting a battery voltage;
b) determining whether the detected voltage of the battery is outside the set voltage range;
c) if the detected voltage of the battery is within the set voltage range, the converter control unit maintaining an MPPT (maximum power point tracking) control mode;
d) If the detected voltage of the battery is out of the set voltage range, the converter control unit switches to the emergency operation mode and controls to output a constant voltage to the DC link unit, characterized in that the DC-DC converter for solar power under the standalone system Control method. The method of claim 1,
B) is a step of detecting whether the battery voltage is "0" solar power DC-DC converter control method under a standalone system. The method of claim 1,
The step b) is a step of determining whether the battery voltage outside the set range in consideration of the total load in conjunction with the smart grid, DC-DC converter control method for solar power under a stand-alone system. The method of claim 1,
And d) controlling the converter controller to turn off the switch (S1) on the MPPT driving path. The method of claim 1,
In step d), at the time of mode switching, the switch S2 which initializes the integrator value is temporarily switched and the control including the operation of multiplying the integrator output value by a certain gain is performed to increase the response speed when the mode is changed. DC-DC converter control method for solar power under standalone system. The method of claim 1,
The step d) is a process for controlling to compensate for the error between the battery voltage set and the output voltage of the DC link unit DC-DC converter control method for a solar system, characterized in that the.

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